Bicycle dual power turning track, rack, pinion, and one-way bearing propulsion system

ABSTRACT

A dual powered propulsion system for use with a human powered vehicle is provided. The system includes a connecting rod with a front end operatively coupled to yoke-connected forearm bars. The system also includes a splitter coupled to a rear end of the connecting rod, wherein the splitter is coupled to a first rack and a second rack that operate with a first and second pinion gear to turn a crank axle. This system supplies rotational power to the crank axle in a single rotational direction as the connecting rod is oscillated up and down and back and forth. Even though a solid connecting rod is used to transfer power from the oscillating forearm bars to the crank axle, the vehicle is steerable to the right or left as a result of the use of a carriage, on rollers, and a turning track operatively connected to the forearm bars.

CROSS REFERENCE TO RELATED APPLICATION'S

This application is a continuation-in-part of the earlier U.S. Utility patent application entitled DUAL POWERED PROPULSION SYSTEM, Ser. No. 14/255,790, filed Apr. 17, 2014, and claims priority to U. S. Provisional Patent Application entitled DUAL POWER ROTARY ROD PROPULSION SYSTEM, Ser. No. 62/215,429, filed Sep. 8, 2015, and claims priority to U. S. Provisional Patent Application entitled BICYCLE DUAL POWER RACK, PINION, AND ONE-WAY BEARING PROPULSION SYSTEM, Ser. No. 62/323,447, filed Apr. 15, 2016, the disclosures of which are hereby incorporated entirely herein by reference.

BACKGROUND OF INVENTION

1) Technical Fields

The Dual Power invention described herein relates generally to a dual power propulsion system for human power vehicles, and more particularly to the use of a turning track, rack, pinion and one-way bearing propulsion system to permit turning of the vehicle while providing torque to the driving wheel of the vehicle from simultaneous or individual use of the rider's arms and legs.

2) Discussion of Related Art

Human powered vehicles employing many different designs for humans to move vehicles have been developed and used throughout the ages. These types of vehicles have been used in many activities, including but not limited to sports, riding to work or store, movement of goods and passengers in commerce, physical exercise, conditioning, or other task. The types of vehicles that can utilize the benefits of a crank axle and driving wheel powered by both the rider's arms and legs include, but are not limited to: bicycles, tricycles, recumbent bikes and trikes, tandem bicycles, human powered airplanes, human powered helicopters, and water craft.

Current and past variations of combined arm and leg powered vehicles have embraced rotating hand cranks, pumping handle bars “up and down” or “back and forth” over the stem of the bicycle, moving one arm up in one direction and the other arm down in the opposite direction simultaneously, moving both arms up and down simultaneously while pulling-on handle bars, and the use of systems containing rods, rotating cables, gears, and racks connecting movable handle bars to the crank axle. An example of this prior art is U.S. Pat. No. 5,328,195, by Graham Sommer, in which a cable is attached to a moveable handle bar that moves “up and down” in unison with a similar movement of the rider's arms and hands. Because U.S. Pat. No. 5,328,195 uses only an unsheathed push-pull cable by itself to transfer power from the pumping arm bars to the crank axle, the rider's arm power is delivered to the crank axle only during the single condition in which the rider is “pulling-up” on the movable handle bars and thus pulling-up on the cable. U.S. Pat. No. 5,328,195 does not provide an ability for the rider to deliver any power to the crank axle when the rider's forearms and hands are “pushing down” on the movable forearm bars. This is because U.S. Pat. No. 5,328,195 enables only the use of standard push/pull cables, which are not sliding inside a stationary cable sheath. Thus, it only causes power to be delivered in the “Pull” mode, and not in the “Compression” or push mode. Because the cable is moving by itself, and not sliding within a stationary sheath, the rider's downward stroke on the forearm bars is like pushing on a string, and hence no power can be delivered to the forward rotation of the crank axle and driving wheel during the “down” stroke. In fact, U.S. Pat. No. 5,328,195 includes as one of its necessary components, a mechanical re-wind mechanism that automatically re-winds the cable during the compression stroke; this ensures no human power can propel the bicycle forward during the rider's “push” stroke on the push/pull cable's “down” stroke.

A second example of variant prior art is USPTO Publication No. US 2007/0114086 A, published May 24, 2007, by Glessner, et. al., and describes a bicycle with two transmissions powered by two aero bars. In the Glessner publication, he enables his invention with the rider sequentially raising and lowering each aero bar separately, first the left one is pulled-up while the right aero bar is simultaneously pushed down, then the left aero bar is pushed-down while the right aero bar is pulled-up. This is quite different from the current invention in which the rider simultaneously pushes and pulls both the right and left forearm bars up together and then pushes them down together. Glessner also does not reference the need nor the use of employing inverted positioned rack and pinion gears in his drive train.

While some vehicles have had modest acceptance in the marketplace, they have been deficient because they cause excess resistance from friction-loss in the operative component parts, they are clumsy to operate, they only provide energy into the crank axle during the pulling or upward stroke of the handle bars, at high speeds some of the designs cause the rider's control of the bicycle to be unstable.

The purpose of this invention is to remedy all of the afore-described and other deficiencies in the prior art relating to arm power assisted cycling.

SUMMARY OF THE INVENTION

In accordance with the invention, the rider is provided an arm assisted drive train in which the arm-powered drive mechanism provides power to the driving wheel, on demand, and can operate regardless of whether or not the rider is using his legs to rotate the pedals. The invention's components are designed so that the rider enjoys “on demand” Dual Power cycling in a stable and controlled manner through use of his elbows and upper arms to steer the bicycle. This is called 4 Point Steering. Dual Power cycling, in which the rider powers the bike using both his arms and legs, also allows the rider to exercise twice as many muscle groups compared to cycling with just his legs, and allows for a more complete cardio, vascular and muscle tissue work-out.

Briefly, the Dual Power Drive Train consists of the following:

-   A) The use of two yoke-connected forearm bars rotating on bearings     over a fulcrum in a partial arc, and always positioned parallel to     the direction of travel of the front wheel. This allows the rider to     use his maximum amount of leverage with his forearms, biceps, and     shoulders to input energy and torque to rotate the driving wheel. -   B) Power rotations of the yoke-connected forearm bars involve the     rider moving them in unison in an upward direction to the sky, and     then in a downward direction toward the ground. Thus, the rider's     yoke-connected forearm bar power movements are always neutral     relative to lateral turning of the front wheel. -   C) The upper arms and elbows provide four separate control points,     and thus 4 point steering. The rider holds his upper arms and elbows     in place to both: 1) turn the front wheel and 2) rotationally pump     the forearm bars in a partial arc. Thus, in order for the rider to     steer the front wheel he must affirmatively move all four control     points in unison in order to make the desired turn to either his     left or right. The rider can intentionally, simultaneously, and     continuously power the bicycle by rotationally pumping the forearm     bars in a partial arc while making his turn. In this way, there's no     unintended lateral turning of the front wheel of a bicycle or     tricycle, which provides the rider with stability and control of the     Dual Powered bicycle. -   D) A turning track is operatively connected to the underside of the     yoke attached to the two forearm bars. A carriage is operatively     connected to the head tube, which is attached to frame of the bike.     This carriage is directly connected to a telescoping rod, which     allows the carriage to move vertically up and down, but does not     allow the carriage to move laterally; -   E) The carriage also has attached to it several rollers, and even     though the turning track moves laterally over them, these rollers     remain horizontally stationary because they're attached to the     stationary positioned carriage; -   F) A raceway on the turning track also comes in contact with the     rollers; as the rider steers the forearm bars left or right, the     turning track correspondingly and simultaneously rotates with the     forearm bars; this is because the turning track rolls over the     stationary positioned rollers; -   G) Operatively connected to the carriage is a connecting rod, which     rotationally moves up and down, as well as back and forth, in unison     with the rider's oscillations of the forearm bars. The connecting     rod is held in its lateral plane by a guide through which the     connecting rod travels; -   H) The rear end of the connecting rod has a T fitting, or splitter,     attached to it, and one of two racks is connected to each side of     the T fitting; one rack is attached to one side of the splitter, and     the other rack is attached to the opposite side of the splitter; -   I) Two pinion gears are positioned with the teeth of each one's     respective rack moving over teeth of its own pinion gear; these     pinion gears are positioned in an inverted manner, one to the other; -   J) A one-way bearing is attached to each of the two pinion gears,     and at the same time is also attached to the outer surface of the     crank axle; -   K) Thus, as the rider oscillates the forearm bars up and down, the     carriage moves up and down in unison with it. The connecting rods     contemporaneously move up and down, as well as back and forth, and     the two racks also move in unison with the connecting rod; -   L) Because the racks are inverted one to the other, with one rack     positioned on top of one of the pinion gears, while the other rack     is positioned on the bottom of the second pinion gear, and the     one-way bearings are positioned between these pinion gears and the     crank axle, the crank axle, chain sprocket, chain, and driving wheel     are always rotating in the direction that propels the driving wheel     and bicycle forward, while the rider rotationally oscillates the     forearm bars up and down. Similarly, if one was to reverse the rack     and pinion gears, which are inverted as described in the preceding     sentence, he would achieve the same result of the crank axle     rotating in the same direction to always propel the driving wheel in     a forward direction; -   M) As a result of the connecting rod being solid or of a tube     configuration, the only way to turn the bicycle's front wheel left     or right is by disconnecting and separating the associated left or     right steering function of the forearm bars and front wheel from the     back and forth movement of the solid connecting rod or tube. This is     accomplished by attaching a turning track to the forearm bars, and     operatively attaching the carriage and its rollers to the bicycle     frame. In this way, the carriage rollers, which cannot move left or     right, permit the forearm bars to move the turning track left or     right, and thus allow the rider to steer the front wheel of the bike     left or right, while simultaneously rotating his forearm bars up and     down, which also moves the connecting rod back and forth. The back     and forth movement of the connecting rod operatively rotates the     crank axle to propel the bike forward during a left or right turn; -   N) The Dual Power Bicycle described herein is designed to improve     many facets involved in the riding of a combined arms and legs     powered bicycle, as compared to a bicycle in which the rider uses     power only from his legs to rotate the crank axle and driving wheel.     Some of these benefits include, but are not limited to: 1) improving     the efficiency of the body's lactate uptake by spreading-out over     more muscle groups of the body the energy utilized in locomotion of     the vehicle, 2) providing a more complete exercise program for the     rider's body by utilizing more muscle groups of the body during the     ride, 3) permitting the rider to ride the bicycle faster, or pull a     greater load, through implementation of additional muscle groups     which inputs more energy into the crank axle and driving wheel, 4)     permitting the rider to have more efficient usage of the available     oxygen in certain parts of his body by spreading it out over more     active muscle groups during a given period of riding time than when     the rider is using just his legs, thus making a more efficient     cardio workout for the rider by engaging both of the rider's upper     and lower body muscle groups, and 5) allowing the rider to transfer     nearly 100% of his arm power into rotating the drive wheel minus a     few percentage points of power (losses) due to friction from general     bearings and the two gears.

This invention, and the objects and features thereof, will be more readily apparent from the following detailed description and appended claims when studied in conjunction with the Drawings.

LIST OF THE INVENTION'S COMPONENT PARTS

Component parts of the invention include:

-   1) Overall bicycle -   2) Top tube -   3) Down tube -   4) Post tube     -   4 a) Post stay -   5) Seat -   6) Head tube -   7) Turning tube -   8) Stem -   109) Fulcrum bar     -   109 a) Forearm bar bearings -   110) Forearm bar -   11) Left crank     -   11 a) Left pedal -   12) Right pedal -   13) Right crank -   14) Front chain sprocket     -   14 a) Second front sprocket     -   14 b) Third front sprocket -   15) Horizontal chain from front sprocket to cassette     -   15 a) chain stay -   16) Rear brake set -   17) Rear wheel and tire -   18) Front wheel and tire -   19) Front forks -   120) Hand grips -   121) Yoke connecting together the two forearm bars     -   121 a) Second yoke connecting together the two forearm bars -   122) Elbow/forearm holders     -   122 a) Elbow/forearm bindings -   123) Attachment connecting the forearm bar to turning track     -   123 a) Attachment connecting yoke to turning track -   124) Turning track that allows the front wheel to turn left or right     while the rider continues to rotationally pump the forearm bars     vertically -   125) Carriage with rollers and over which the turning track rotates     during a turn     -   125 a) Rollers attached to the carriage, and over which the         turning track travels     -   125 b) Connection attachment between the telescoping rod and the         carriage -   126) Telescoping rod     -   126 a) Pin holding bottom of telescoping rod onto head tube         bracket -   27) Connecting rod between the carriage and rod end bearing attached     to the splitter     -   27 a) Horizontal bridge connecting rod that connects the         carriage to the main diagonally positioned connecting that is         attached to the splitter on its rear end -   28) Guide that holds the connecting rod in a continuous lateral     plane -   29) Rod end bearing connecting the connecting rod with the splitter -   30) Housing that contains and protects the racks, pinion gears, and     one-way bearings -   31) Splitter -   32) First rack that travels under the first pinion gear     -   32 a) First pinion gear that rotates on top of the first rack     -   32 b) First one-way bearing positioned between the first pinion         gear and the crank axle     -   32 c) One of two rollers upon which the rack travels, and which         keeps the rack traveling over its corresponding pinion gear -   33) Second rack that travels on top of the second pinion gear     -   33 a) Second pinion gear that rotates below rack 33     -   33 b) Second one-way bearing positioned between second pinion         gear and crank axle     -   33 c) One of two rollers upon which the rack travels, and which         keeps the rack traveling over the pinion gear -   34) Crank axle housing -   35) Crank axle -   36) One of two bearing sets over which the crank axle rotates inside     the crank axle housing

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1 through 5 are illustrations of various views of Configuration I showing a dual power rack and pinion gear and propulsion system; 6 through 12 are illustrations of various views of different component assemblies for Configuration II of the Dual Power Bike. FIGS. 13 through 17 are illustrations of different components and assemblies for Configuration III of the Dual Power Bike.

FIG. 1 is an oblique view of Configuration I showing a road bike that has installed on it the Dual Power invention with a rack and pinion propulsion system;

FIG. 2 is an oblique illustration of Configuration I showing the forearm bars, turning track, and carriage, wherein this illustration is taken from a left rear view of the bike;

FIG. 3 illustrates Configuration I showing the connecting rod, splitter, racks, pinion gears, and rollers that are positioned around the crank axle;

FIG. 4 is a cut-a-way view of Configuration I from FIG. 3A showing the racks, pinion gears, one-way bearings, rollers, and crank axle;

FIG. 5 is an illustration of Configurations I, II and III showing the elbow platforms and holders used to hold the elbows in a stationary position.

FIG. 6 is an oblique frontal view of an example of a Dual Power Bicycle, shown in Configuration II, as described herein, and in which the rider is able to use: a) his legs by themselves, or b) both his arms and legs at the same time to power the bicycle when designed according to the enablement of this invention. In Configurations II and III, the two different drives that comprise the bicycle's drive system consist of a) Upper Front Drive System 100, that is applicable for both Configurations II and III, Middle Drive System 200 for Configuration II, Middle Drive System 300 for Configuration III, and Lower Rear Drive System 400 applicable to both Configurations II and III;

FIG. 7 illustrates the Dual Power forearm/bars in four different positions: FIGS. 7a -1, 7 a-2, 7 a-3, and 7 a-4. Each position is representative of the forearm/hand bars being pulled-up and pushed down in rotational power strokes by the rider as he provides Dual Power to the crank axle and driving wheel during a full 360 degree rotation of the crank;

FIG. 8 is an oblique perspective view of Configuration II and III from the right rear location of Upper Drive System 100, showing the fulcrum rod, “On Demand” forearm/hand bars, turning track attached to the underside of the forearm/hand bars, and which also acts as a yoke to connect them together. Other parts include the telescoping rod, connecting bridge rod, and rollers inside the turning track, and carriage.

FIG. 9 is an oblique perspective view of Configuration II looking toward the upper left front of the Dual Power bike, and illustrates the positioning of the horizontal drive line connected to the crank on its front end, then traversing through a gap between the top of the front tire and the crown in the forks, and connecting on its rear end with the front bevel gear located at the top of the down tube. It also shows the bevel gears, spur gears, sprockets and chain;

FIG. 10 is a perspective view of Configuration II from the left front of the Upper Drive System 100. In this illustration the cam, cam follower, and spring loaded bracket attached to the cam follower are shown. They are positioned on the front of the bike near the head tube and ahead of any gears that may be a part of the Dual Power drive train. Also shown are the telescoping rod, upper front crank, connecting bridge rod, and horizontal drive line;

FIG. 11 is an oblique view of Configuration II from the rider's left side and shows the component parts used in the upper section of Middle Drive System 300 for Configuration II. These include two bevel gears and their bearings, two spur gears, upper front sprockets and chain;

FIG. 12 is an oblique view of Configuration II from the bicycle's left side showing the component parts used in the lower section of Middle Drive System 300.

FIG. 13 is a front side diagonal view of the left side of the Dual Power bicycle in Configuration III format, and shows the Middle Drive System 300 drive train partially consisting of a rotating horizontal drive line that is positioned from the crank on its front end, traversing through a gap between the crown of the forks and the top of the front tire, and connecting-up with a bevel gear inside the top of the down tube;

FIG. 14 is a left frontal oblique view primarily of the components used in the Upper Front Drive System 100 and 200, and for which such parts are similar for application on both Configurations II and III;

FIG. 15 is an oblique view of Configuration III taken from a left rear location of the front of the Dual Power bike, and shows many of the component parts used in Upper Drive System 100 and Middle Drive System 300. It also shows some housings for component parts used in the Drive Train for Configuration III;

FIG. 16 is a cut-away view of Middle Drive System 400 as designed and used in Configuration III of the Invention. The parts include the hub and its internal gears located in front of the upper set of bevel gears, two bevel gears positioned inside and near the top of the down tube, a diagonally positioned drive line, and a second set of bevel gears located at the intersection of the down tube and the crank axle housing. All of these parts are located inside the down tube;

FIG. 17 illustrates component parts used in Lower Drive System 400, which are used in Configuration III. These parts include the crank axle and its bearings, and pedal cranks.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION I. Embodiments of Configuration I

In the following description and accompanying drawings, like numbers refer to like parts whenever they occur. In addition, while the following enablement refers to many component parts for Configuration I of the invention operating at specific positions within the overall Dual Power drive system, some of these parts may be shifted to different locations within the overall drive system, and still maintain complete functionality of the Dual Power drive system. An example of this is with rack 32, which in the current design is positioned underneath pinion gear 32 a, it could also be positioned on top of pinion gear 32, and operate just as well. Of course if this design change is implemented, then rack 33 would need to be re-positioned and located under pinion gear 33 a. (See FIGS. 3 and 4)

A. Dual Power Drive Train for Configuration I

The Dual Power Bicycle consists of bicycle frame 1, and has attached to its turning tube 7 and stem 8, a perpendicularly mounted fulcrum rod 109. This fulcrum rod 109 serves two purposes, a) provides the rider with the ability to steer the front wheel 18 of bicycle 1 with his elbows and upper arms by causing the turning tube 7 to naturally steer right or left when he turns it 7 with his upper arms and elbows on the forearm bars 110 and elbow holders 22. The rider accomplishes a left turn by pushing his right elbow and upper arm forward, and pulling-back with his left elbow and upper arm. A right turn is accomplished by reversing the preceding directions with his elbows and upper arms. Because the forearm bars 110 are attached to the fulcrum rod 109 with bearings 109 a, this permits the rider to simultaneously input muscle generated power from his biceps, forearms, and shoulders into torque that rotates the crank axle 35. Torque is created when the rider rotationally pumps “up and down” the forearm bars 110 at a rate as fast or faster than the rider is turning the crank axle 35 from pumping the pedals 11 a and 12 with his legs. The fulcrum rod 109 has on each end a bearing 109 a, and attached to each of these bearings 109 a is the rear end of one of two forearm bars 110. Thus, as the rider “pulls-up and pushes-down” on the hand grips 120 of forearm bars 110, the rear end of each of these forearm bars 110 pivots on fulcrum rod 109 and bearings 109 a, causing a cyclical angular displacement of the forearm bars 110 as they rotate lineally along the path of an arc. (See FIGS. 1, 2 and 7)

If the rider is going to use vigorous power during the down stroke of the forearm bars 110, then it is useful for him to use the forearm/elbow bindings 122 a as illustrated in FIG. 5. In this situation, before riding the Dual Power Bike 1, the rider will first attach the bindings 122 a onto his forearm and elbows. Then the rider pushes his bindings 122 a into the receiving hole in platforms 122 so that they 122 a are not loose. The rider then commences his rotational up and down power strokes with the forearm bars 110. Unless the rider uses the bindings 122 a to fasten his elbows and forearms into the platforms 122, then when he is vigorously pushing down with his hands and forearms during the down stroke, his elbows and forearms may lift off of the platforms 122. This condition may result in less power being delivered into the crank axle 35. The bindings 122 a may be quick release bindings 122 a coupled to the elbow platform 122, wherein the quick release bindings 122 a are configured to releasably couple a rider's elbows to the elbow platform 122.

The forearm bars 110 are connected together with two yokes 121 and 121 a. The function of yokes 121 and 121 a is to tie together the two forearm bars 110 so that they can only move together in unison, one with the other, rotationally “up and down”, or be steered in unison left or right. Thus as the rider grips hand grips 120, and rotationally pumps forearm bars 110 “up and down” in a complete cycle, this function causes the turning track 124 and carriage 125 to also rotationally oscillate up and down; simultaneously connecting rod 27 moves in unison with them both up and down as well as back and forth. (See FIGS. 1, 2, and 3)

Attached to turning track 124 is a carriage 125. Carriage 125 is attached to turning track 124 through rollers 125 a. The carriage 125 and rollers 125 a are operatively coupled to the frame with telescoping rod 126. Telescoping rod 126 allows the carriage 125 and rollers 125 a to move vertically while prohibiting movement side to side. Thus, as the rider steers the forearm bars 110 to either the left or right, he is simultaneously rotating turning track 124 as well as the turning tube 7, and thereby steering the front forks 19 and front wheel 18 to the left or right. Because the carriage 125 and rollers 125 a are held horizontally stationary, the carriage 125 and rollers 125 a permit the turning track 124 to roll over the rollers 125 a, while also allowing the rider to rotationally pump the forearm bars 110 vertically, which is operatively inputting power into the driving wheel 17 and moving the bicycle forward. (See FIGS. 1 and 2)

A horizontally positioned connecting rod 27 a is attached to carriage 125 on one end, and on its opposite end, it 27 a is attached to the front end of the diagonally positioned connecting rod 27. Thus, as carriage 125 is rotationally moved up and down by the rider oscillating the forearm bars 110, the horizontal connecting rod 27 a is also rotationally moved up and down. This causes connecting rod 27 to simultaneously move both up and down as well as back and forth.

These components serve two purposes, the first is to provide the rider with four point steering, which the rider uses to make any turn to his right or left by simply turning in unison both his forearms and hands in the desired direction. Four point steering of the forearm bars 110 uses four separate human touch points to steer the front wheel 18. The four human touch points are: 1) left forearm/elbow, 2) right forearm/elbow, 3) left hand and 4) right hand that are all placed onto the forearm/hand bars 110 and grips 120, respectively. Thus, in order for the rider to steer the front wheel 18 he must affirmatively and simultaneously move all four touch points in unison toward the direction of his desired turn to the left or right.

Normally the use of a solid drive line 27 in Configuration I would preclude the rider from being able to turn the bicycle 1 to the right or left. This is because the solid drive line 27 is inputting power to the crank axle from the oscillating forearm/hand bars. In order to input this power, it 27 cannot be flexible. This problem can be overcome by separating and making independent the turning function from the forearm/had power function. This is accomplished by use of the turning track 124 affixed to the forearm/hand bars, carriage 125 affixed to the rollers 125 a, these rollers permitting the turning track to roll over the carriage during a turn, telescoping rod 126 affixed to the head tube 7, and connecting rod 27 operatively connected to the crank axle.

The rear end of connecting rod 27 is connected to splitter 31, which is in turn connected to racks 32 and 33. The geometric positioning of these parts, as shown in FIGS. 1 and 3, cause racks 32 and 33 to oscillate back and forth in reaction to the rider rotationally moving his forearm bars 110 up and down (See FIGS. 1, 3, and 4). One of the racks, in this example rack 32, is mounted below its corresponding pinion gear 32 a. The second rack 33 is mounted on the top of its corresponding pinion gear 33 a. Because rack 32 is mounted below its corresponding pinion gear 32 a, and rack 33 is mounted on top of its pinion gear 33 a, when the splitter 31 is pulled and pushed back and forth by the connecting rod 27, the pinion gears 32 a and 33 a rotate in opposite directions, one from the other. However, each pinion gear 32 a and 33 a rides on a one-way bearing, 32 b and 33 b, respectively. Thus crank axle 35 is always rotating in one single direction, which will continuously and operatively rotate driving wheel 17, so long as the rider is oscillating forearm bars 110 at a rate that is as fast or faster than he is pedaling his legs. (See FIGS. 1, 3, and 4)

Because one-way bearings 32 b and 33 b, respectively, are positioned between crank axle 35 and pinion gears 32 a and 33 a, the one-way bearings 32 b and 33 b allow the rider to enjoy “on demand” Dual Power bicycling. This occurs as a result of the fact that each one-way bearing 32 b and 33 b must be rotated by its respective pinion gear 32 a and 33 a at a rotational rate that is equal to or greater than the revolutions per minute which the rider is pedaling the crank axle 35 with his legs. (See FIGS. 1, 3, and 4) Thus, so long as the rider is rotationally oscillating his forearm bars 110 at a rate that causes the pinion gears 32 a and 33 a, along with their respective one-way bearings 32 b and 33 b, to rotate at a faster rate than the rider is pedaling with his legs, the forearm bars 110 will be continuously and singularly rotating the crank axle 35 and driving wheel 17 in the same forward direction. If the rider is rotationally oscillating the forearm bars 110 at a rate that is equal to the RPM at which he is rotating pedals 11 a and 12 to turn crank axle 35, then torque will be derived from the rider's forearms, biceps, and shoulders, as well as his legs, to rotate the crank axle 35 and driving wheel 17. And finally, if the rider's legs and pedals 11 a and 12 are rotating crank axle 35 at a faster rate than he is oscillating his forearm bars 110 to rotate the crank axle 35, then all the power that provides torque to turn crank axle 35 will be coming from the rider rotating just his legs. (See FIGS. 1,2,3, and 4)

The connecting rod 27 is held in its vertical plane by virtue of it 27 traversing through a guide 28, that is attached to the down tube 3. This guide 28 controls the path of lateral travel by precluding the connecting rod from being able to move laterally away from the down tube 3.

A set of rollers 32 c and 33 c, are attached to housing 30, and positioned on the bottom and top of their respective racks 32 and 33. The roller sets 32 c and 33 c cause the teeth of their respective racks 32 and 33 to be continuously meshed into the teeth of their respective pinion gears 32 a and 33 a. Thus, even though racks 32 and 33 are moving back and forth over their respective pinion gears 32 a and 32 a, the rollers 32 c and 33 c, respectively, are held stationary because of their 32 c and 33 c attachment to the stationary housing 30. This causes the racks, 32 and 33, to just roll over the rollers 32 c and 33 c, respectively, as their 32 and 33 teeth, which are meshed into the teeth of pinion gears 32 a and 33 a, respectively, rotate their respective pinion gears 32 a and 33 a. The inverted rotation of pinion gears 32 a and 33 b cause their respective one-way bearings 32 b and 33 b to cause crank axle 35 to continuously rotate in only the forward direction as a result of the rider rotationally oscillating his forearm bars 110. (See FIGS. 1,2,3, and 4) This condition will be operative so long as the rider is oscillating his forearm bars 110 at a rate that causes the crank axle 35 to rotate as fast as or faster than the rider is pedaling the crank axle 35. In additional embodiments, as shown in FIG. 3B, set of rollers 32 c and 33 c may be replaced with rack support casings 32 d and 33 d respectively. Rack support casings 32 d and 33 d support racks 32 and 33 respectively as they travel over the pinion gears 32 a and 33 a.

II. Embodiments of Configurations II and III

According to embodiments, the function of the rider simultaneously using both his arms and legs, prosthetic or otherwise, to input torque into the driving wheel is called Dual Power. The components of this invention are designed so that the rider enjoys Dual Power bicycling in a stable and controlled manner through use of 4-point steering. He can reduce his exercise time by up to 40%, because he is using both his upper and lower body muscles. The rider can also increase his speed as a result of inputting more torque into the driving wheel.

The use of two yoke-connected forearm/hand bars rotating over a fulcrum rod in a partial arc, and always positioned parallel to the direction of travel of the front wheel, allows the rider to use his maximum amount of leverage with his forearm/hand bars, shoulders, and upper body to input energy and torque into rotating the crank axle. This torque is then transferred to the driving wheel through application of currently used bicycle sprockets and chains.

Rotation of the yoke-connected forearm/hand bars starts and ends with the rider moving them in an upward direction toward the sky, and then in a downward direction toward the ground. Thus, the rider's yoke-connected forearm/hand bar power movement is always neutral relative to a lateral steering of the front wheel. Many examples of prior art operate from a sequential pushing or pulling on one side of the handle bars and then the other side, which can lead to an unwanted and unsafe steering of the front wheel.

Four point steering of the forearm/hand bars provides four separate human touch points to steer the front wheel. They are: 1) left elbow, 2) right elbow, 3) left hand and 4) right hand are all placed onto the forearm/elbow bars and handgrips. This is their riding position while the rider is a) steering the front wheel and b) rotationally pumping the forearm/hand bars together in the same up and down direction to input power to the crank axle. Thus, in order for the rider to steer the front wheel he must affirmatively and simultaneously move all four touch points in unison toward the direction of his desired turn to the left or right. In this way, there is no unintended lateral steering of the front wheel of the cycle, unless the rider chooses to intentionally make a turn and affirmatively does so.

The Dual Power Bicycle described herein is designed to improve many facets involved in the riding of a combined arms and legs powered bicycle. Some of these improved facets include, but are not limited to: 1) improving the efficiency of the body's lactic acid uptake by spreading-out over more muscle groups of the body the energy utilized in locomotion of the vehicle, 2) providing a more complete cross-training exercise program for the rider's body by utilizing more upper body muscle groups during the ride, 3) permitting the rider to ride the bicycle faster—or pull a greater load—through the implementation of additional muscle groups to input more energy into the crank axle and driving wheel over a given amount of time, and 4) permitting the rider to have a more efficient usage of the available oxygen in certain parts of his body by spreading it out over more active muscle groups during a given period of riding time than when the rider uses just his legs, and 5) making a more efficient cardio and respiratory workout for the rider by engaging both of the rider's upper and lower body muscle groups and burning more calories during a set amount of time. Because the rider is more efficiently using his cardio and respiratory systems together, he can spend less time on the bike to satisfy these exercise requirements.

A. Parts Used in Configurations II and III

List of the Invention's Component Parts in addition to the component parts listed previously:

-   -   1) Basic Parts used in most all standard bikes are denominated         as parts 1-8, 11, 11 a, 12, 13, 14, 15, 16, 18, and 19 in this         Application and are not unique to the current invention;     -   2) Parts that are in the 100 series of numbers describe those         components within the Upper Drive System 100, and these same         components are used for all 3 Configurations I, II and III. The         parts in the Upper Drive System 100 are numbered 109, 109 a,         110, 120, 121, 122, 123, 123 a, 123 b, 124, 125, 125 a, 125 b,         126, and 126 a;     -   3) Component parts used in the Upper Front Drive System that are         used in both Configurations II and III are numbered 226, 226 a,         226 b, 227, 227 a, 228, 229, 230, 231 and 232.         -   a. Parts used in the Middle Drive System for Configuration             II are designated in the 300 series, and they include             numbers 333, 334 a, 334 b, 335, 336, 337, 338, 338 a, 339,             339 a, 340, 341, and 342;         -   b. Parts used in Middle Drive System and found in             Configuration III are designated as Series 400, and they             include numbers 443, 444, 445 a, 445 b, 446, 447, 448 a, 448             b, 449 a, and 450;

The part number and nomenclature for such parts are as follows in this list of component parts shown in the Drawings illustrating this invention for Configurations II and III:

15) Right Chain Rear Sprocket, Derailleur, and Cassette a) Chain Stay

-   110) Pumping Forearm/Hand Bars; -   120) Forearm Bar Hand Grips attached to front end of forearm/hand     pumping bars; -   121) Yoke and attachment connecting yoke to forearm bars;     -   121 a) Yoke and attachment brackets connecting yoke to forearm         bars; -   122) Forearm/Elbow Support Platforms;     -   123 a,b,c) Brackets connecting the Turning Track to the Forearm         Bars; -   124) Turning Track; -   125) Carriage inside Turning Track;     -   a) Carriage's support rollers;     -   b) Horizontal connection rod between carriage and top end of         telescoping rod; -   126) Telescoping Rod;     -   126 a) Pin connecting telescoping rod to the head tube; -   226) Oscillating vertical connecting bridge rod between the carriage     and upper front crank, and may have telescoping capability;     -   a) Upper universal rod end bearing connecting upper end of upper         front vertical bridge rod to horizontal rod;     -   b) Lower universal rod end bearing attached to lower end of         upper front vertical connecting bridge rod to outer end of upper         front crank; -   227) Upper Front Crank     -   a) Upper front crank bearing; -   228) Bracket holding in place the crank and crank bearing, and that     is attached to the head tube; -   229) Horizontal Solid rotating drive line attached to the upper     front crank on its front end, then traveling under and through the     crown of the forks, and attaching on its rear end to a set of bevel     gears mounted on the down tube; -   230) Cam—The cam may be shaped in a generally elliptical shape, and     its shoulders are generally located 180 degrees apart. The purpose     of the cam and cam follower is to push the crank over its top and     bottom dead center, which are normally at the zero and 180 degree     marks; -   231) Cam follower—The cam follower is circular in shape and rotates     directly over the circumferential surface of the cam. The cam     follower is attached to a set of springs that contract and expand     with the rotation of its cam, and thus provide the force necessary     to push the flywheel across its top and bottom dead center     locations; -   232) Cam Follower Spring Mechanism-springs may be indirectly     attached to the Cam Follower through this mechanism. The compression     and expansion of these springs force the cam follower to be in     contact with and ride the circumferential surface of the cam. The     purpose of them is to provide sufficient downward force on the cam     follower to cause it to push and rotate the cam, and thereby the     flywheel, over both its top and bottom dead center positions; -   333) Transmission Housing located at the top of the down tube and     holds in place the set of bevel gears, spur gears, and upper front     sprockets; -   334) Bevel gear set located between the rotating horizontal rod and     the upper front sprocket of the chain or belt;     -   a) Bevel gear (a) mounted on the end of the rotating horizontal         rod;     -   b) Bevel gear (b) mounted perpendicular to bevel gear (a), and         whose axle is connected on its opposite end to spur gear (a); -   335) Axle connecting bevel gear (b) to spur gear (a); -   336) Spur gear (a); -   337) Spur gear (b); -   338) Mid-level chain or belt sprocket;     -   a) Second alternative upper front sprocket used in the design         wherein the Dual Power drive system is fitted with multiple         sprockets for varying the rate of oscillations per minute for         the rider's rotational up and down strokes of the forearm/hand         bars; -   339) DeRailleur set that will move the Dual Power drive chain or     belt from one upper front sprocket to another in order to permit the     rider to vary the rate of oscillations per minute of his rotational     up and down movement of the forearm/hand bars;     -   a) Lever to cause the derailleur to move the chain from one         sprocket to another; -   340) Chain or belt connecting the upper front sprocket to the lower     rear sprocket; -   341) Lower rear chain/belt sprocket which is attached to the crank     axle; -   342) One-way bearing—The inner race of the one-way bearing is     mounted upon the lower rear axle, and in Configuration II, its outer     race is attached to the lower rear sprocket. Its purpose is to     permit the rider to have “on demand” control of inputting Dual Power     into the bicycle's driving wheel through the rotational pumping his     forearm/hand bars. -   443) Cover for the orifice located in the underside of the down tube     and into which the horizontal rotating power rod enters the interior     of the down tube; -   444) Front bearing set supporting the rear end of the horizontal     power rod at the location where orifice in the down tube where the     horizontal power rod enters the underside of the down tube; -   445 a and b) Bevel gear set whose axles are positioned diagonally     one to the other. They're located just inside the orifice where the     horizontal power rod enters the underside of the down tube. These     two bevel gears are meshed together and transfer torque from the     rotation of the horizontal power rod into torque to rotate the     diagonally positioned rotating power rod located inside the down     tube; -   446) Diagonally positioned rotating drive line inside the down tube; -   447) Collar and bearing surrounding the upper end of the diagonally     positioned rotating rod and provides horizontal support for the     rotating power rod located between the interior side walls of the     down tube; -   448 a and b) Set of bevel gears located at the junction of the base     of the down tube and the crank axle. Bevel gear 348 a is attached to     the lower end of the diagonally positioned rotating power rod, and     is meshed with bevel gear 348 b. This bevel gear is attached     directly to the crank axle, and provides torque to it from power     generated from the rider pumping his forearm/hand bars; -   449) Hub, with internally mounted gears, positioned inside the down     tube, and located in front of the upper bevel gear set;     -   a) Lever to move gears inside Hub 349; -   450) One-way bearing located between bevel gear 348 b and crank axle     35;

III. Additional Embodiments of the Invention

In the following description and accompanying drawings, like numbers refer to like parts whenever they occur. In addition, while the following Enablement refers to many component parts of the invention operating at specific positions within the overall dual power drive system, some of these parts may be shifted to different locations within the overall drive system, and still maintain complete functionality within the Dual Power drive system. An example of this is with the positioning of the cam and spring-loaded cam follower, wherein they are placed in front of the head tube in this Enablement of the invention, but to someone knowledgeable and skilled in the art, will recognize that they can be placed on the lower crank axle and still have the cam and cam follower force the upper front crank over its top and bottom dead center positions.

There are two configurations for the additional embodiments of the invention, Configurations II and III. The differences between them is that in Configuration II, there is a sprocket 338 and chain 340 that traverses along the exterior side of the down tube 3 and drives the crank axle 35; however in Configuration III, a rotating solid drive line 446 is located inside the down tube 3, and substitutes for the chain 340 to transfer torque from the top of the down tube 3 to drive the crank axle 35 from power provided by the rider rotationally pumping the forearm/hand bars 110 up and down. The invention also allows the rider to use his upper body muscles by rotationally pumping the forearm/hand bars 110, in conjunction with employing his lower body muscles, by pumping his legs on the pedals 11 a and 12; or the rider can use just his lower body muscles by pumping his legs on the pedals 11 a and 12 and not moving his upper arms. Thus the rider reduces his cardio and respiratory exercise time while simultaneously building-up the muscle mass in his arms, shoulders and upper back. These continuous and unified forearm/hand power strokes cause the rider to efficiently exercise and build muscle mass in his upper body muscles while simultaneously exercising his legs. Consequently, the Dual Power drive train can cut the rider's exercise time up to 40%, and provides a low impact upper body exercise format to allow disabled people to exercise their whole body riding the cycle 1 at the same time. This drive train also allows the rider to input more torque into the crank axle 35 by using both his upper body and lower body muscles simultaneously which can result in faster speeds and hauling more pay load.

In both Configurations II and III, the description of the Dual Power drive train is divided into four basic segments, they are: a) Upper Front Drive System 200 with all of the 200 series parts being used in both Configurations II and III, b) Middle Drive System 300 (Middle Drive Parts used only in Configuration II), and Middle Drive System 400 (Middle Drive Parts used only in Configuration III). A general summary for Configuration III is:

-   -   1) The Dual Power cycle uses a pair of forearm/hand bars 110         which the rider rotationally pulls-up and pushes-down together,         in unison, and in power strokes, to create and deliver torque to         the lower crank axle 35, in conjunction with the rider rotating         his legs/pedals 11 a and 12;     -   2) The rider can also ride his cycle using only his legs to         rotate the pedals 11 a and 12 and lower crank axle 35;     -   3) Yokes 121 and 121 a connect the two forearm/hand bars 110, so         they move in unison together and in the same direction; these         yokes 121 and 121 a are also the attachment points for fastening         the upper front end of the connecting bridge rod 126 to the         forearm/hand bars 110, and attaching turning track 124 to the         forearm bars 110;     -   4) The rear end of the forearm/hand bars 110 are connected to a         fulcrum bar 109 with a set of bearings 109 a. The top of the         back end of each forearm/hand bar 110 has a platform 122         attached to it, which provides stability, and support for the         rider's elbows to rest, while leveraging the use of muscles in         his shoulders and arms to create and deliver maximum upper body         power to the lower crank axle 35 and driving wheel 17;     -   5) The forearm/hand bars 110 are connected together with a yoke         121, and attached to the yoke is an upper front connecting         bridge rod 226;     -   6) The bottom end of the connecting rod 226 is attached to an         upper front crank 227, which can be located just above the front         wheel 18, and the back end of the crank 227 is attached to a         solid rotatable drive line 229;     -   7) The rear end of the solid rotatable drive line 229 can be         attached to the front end of one of two bevel gears 334 a, 334         b, the second bevel gear 334 b has its teeth meshed into the         teeth of the first bevel gear 334 a, and this second bevel gear         334 b is positioned perpendicular to the first, or front bevel         gear 334 a;     -   8) The axle 335 for the back side of the second, or rear, bevel         gear 334 b may have attached to it a spur gear 336, and meshed         with this first spur gear 336 is a second spur gear 337 that is         positioned adjacent to the first spur gear 336.     -   9) Attached to the axle upon which the second, or adjacent spur         gear 337 rotates, is one or more sprockets 338, 338 a, and onto         this sprocket 338 is mounted a chain 340; and     -   10) The front end of the chain 340 is positioned over the teeth         of one of these mid-level sprockets 338, 338 a, and the chain's         340 rear end is positioned over the lower rear sprocket's 341         teeth, which is affixed to the crank axle 35.

In applying the forgoing Dual Power components to the rider's bicycling experience, he grasps the hand grips 120 of the forearm/hand bars 110, places his elbows on top of the platforms 122, and then rotationally pulls-up and pushes-down on the front of the forearm/hand bars 110, always using power strokes. Simultaneously he rotates the pedals 11 a and 12 with his legs. Because the back of the forearm/hand bars 110 are attached to bearings 109 a that rotate over the fulcrum bar 109, the rotational up and down oscillations of the forearm/hand bars 110 cause the yoke 121, and its attached connecting bridge rod 226, to move up and down. Since the bottom end 226 b of the connecting bridge rod 226 is attached to the outside end of the crank 227, and the crank's 227 inside end is attached to the rotatable but solid driveline 229, this causes the vertically moving connecting rod 226 to rotate the crank 227 a full 360 degrees with each up and down rotational oscillation of the forearm/hand bars 110.

The 360 degree rotation of the crank 227 then causes the rotatable solid drive line 229, to which the inner end of the connecting rod 226 is attached to the front end of this rotatable drive line 229, to also rotate 360 degrees with each oscillation of the forearm/hand bars 110. As a result of the rear end of the rotatable driveline 229 being connected to the axle of the first, or front, bevel gear 334 a, the teeth of this bevel gear 334 a also rotate 360 degrees. The teeth of this front bevel gear 334 a are meshed into the teeth of a second bevel gear 334 b, which is positioned perpendicular to the first, or front, bevel gear 334 a. The back side of this second, or rear, bevel gear 334 b can have attached to it a chain sprocket 338. Thus as the teeth of these two bevel gears 334 a, 334 b rotate 360 degrees, this chain sprocket 338 also rotates 360 degrees.

Alternatively, the axle 335 of the second bevel gear 334 b may be attached to a first spur gear 336. The first spur gear 336 may have positioned adjacent to it a second spur gear 337. On the back side of the second spur gear 337 may be positioned the mid-level chain sprocket 338, which may have multiple sprockets 338 a adjacent to one another. An upper front chain derailleur 339 may be used to move this mid-level chain 340 from the teeth of one chain sprocket 338 to another 338 a.

While the front end of the chain 340 is positioned over the teeth of the front sprocket 338, the rear end of the chain 340 is draped over the teeth of a second sprocket 341, called the lower rear sprocket 341, which is attached to the crank axle 35. Thus, as the rider uses his upper body muscles and forearms to pull-up and then push-down with power strokes, jointly and in unison, on the forearm/hand bars 110, the afore-described drive train causes power from his upper body muscles to input torque and rotate the crank axle 35, which in turn rotates the driving wheel 17 of the bicycle 1, through use of standard industry chains 15 and sprockets 14 positioned from the front sprocket 14 and derailleur 15 to the rear cassette 15. This Dual Power drive train may also be used on other vehicles and applications, such as, but not limited to tricycles, human powered vehicles, airplanes, watercraft and the like.

In order to allow steering of the front wheel 18 to the left or right, while the rider is simultaneously pumping his forearm/hand bars 110 vertically and rotationally, the steering function of the turning track 124 and forearm/hand bars 110 must be separate and independent from the vertical and rotational movement of the stationary positioned upper front crank 227. This can be accomplished through the use of a telescoping rod 126, carriage 125 and curved linear rolling track 124. The rolling track 124, or other such device, is attached to the forearm/hand bars 110, and moves laterally and vertically in unison with them. As the turning track 124 is turned to the right or left, its inner surfaces slide over the rollers 125 a, which are attached to the carriage 125. The carriage 125 is held in a stationary position, free from lateral movement. However, it can still move vertically up and down, because it is attached to the top of a telescoping rod 126 that moves in and out in unison with the vertical movement of the turning track 124. The base 126 a of the telescoping rod 126 is affixed to the head tube 6 of the bike 1, which thereby precludes lateral movement of the carriage 125, even though the forearm/hand bars 110, turning tube 7, and front wheel 18 are turned by the rider to his right or left.

Other vehicles, such as a tricycle may include two front wheels, wherein the steering is configured to turn the two front wheels, which operate with tie rods or the like; a marine vehicle with a rudder or propeller being controlled for steering; a flying vehicle with ailerons, elevators and/or rudder to control steering of the flying vehicle. In these embodiments, the turning track 124 may be coupled to a steering system.

A bicycle 1, or other type of human powered vehicle, airplane, or watercraft utilizing the Dual Power drive train, can be designed in an upright riding geometry, or alternatively, in a recumbent configuration. It is anticipated that for someone schooled in the art of designing drive trains for upright and recumbent bicycles, tricycles, and other such vehicles, the basic components can be modified in minor ways that will not alter the functionality of the current invention.

IV. Dual Power Cycle Drive Train for Configurations II and III

A. Upper Drive System 100 for Both Configurations II and III:

The UPPER FRONT DRIVE SYSTEM 100 for the dual power bicycle 1 consists of a fulcrum rod 109 that is attached to the stem 8 of the bicycle 1. Two forearm/hand bars 110 are perpendicularly mounted at their rear ends 110 to the fulcrum rod 109 through a set of bearings 109 a. Turning track 124 is affixed to the forearm/hand bars 110. Platforms 122, upon which the rider places his elbows and forearms, are attached to the top of the forearm/hand bars 110. A carriage 125, with rollers 125 a attached to it 125, is located inside the turning track 124. The carriage 125 and its rollers 125 a stay in a stationary position relative to the crank 227, while the turning track 124 rotates over them 125 a when the rider turns the bike 1 to either his right or left direction. (See FIGS. 7, 8, 8 a, 8 b, 9, 14 and 15) These components serve two purposes. The first is to provide the rider with four point steering, which the rider uses to make any turn to his right or left by simply turning in unison both his forearms and hands in the desired direction. Four point steering of the forearm/hand bars 110 provides four separate human touch points to steer the front wheel 18, the four human touch points being: 1) left forearm/elbow, 2) right forearm/elbow, 3) left hand and 4) right hand that are all placed onto the forearm/hand bars 110 and grips 120. Thus, in order for the rider to steer the front wheel 18 he must affirmatively and simultaneously move all four touch points in unison toward the direction of his desired turn to the left or right. Because the forearm/hand bars 110 are attached to the fulcrum rod 109, and it 109 is attached to the stem 8, and the stem 8 is attached to the turning tube 7, with the turning tube 7 attached directly to the crown of the front wheel forks 19, any turning of the forearm/hand bars 110 causes the turning tube 7 and front wheel 18 to turn in unison with it 110. (See FIGS. 8,9, 14, and 15) The second purpose is to allow the rider to simultaneously input power from his upper body into rotating the crank axle 35. This occurs when the rider pulls-up and then pushes-down in continuous power strokes on the forearm/hand bars 110 in a rotational arc. Torque is created when the rider rotationally pumps the forearm/hand bars 110 at a rate that is as fast as or faster than the rider is pedaling the crank axle 35 with his legs. The fulcrum rod 109 has on each end a bearing 109 a, and attached to each of these bearings 109 a is the rear end of one of two forearm/hand bars 110. Thus, as the rider “pulls-up and pushes-down” on the front of the forearm/hand bars 110, the rear end of each of these forearm/hand bars 110 pivots on the fulcrum rod 109 and bearings 109 a, causing a cyclical angular displacement of the forearm/hand bars 110 as they move lineally along the path of an arc (see FIGS. 7a -1 thru 7 a-4). The path of this arc is determined by a) the radius of the arc, and b) the length of the connecting rod 226, and c) circumference of the crank 227. (See FIGS. 7a -1 thru 7 a-4).

The forearm/hand bars 110 are connected together through a turning track 124 that is located below and between both forearm bars 110. Attached on the underside of each of them 110 (See FIG. 7) is the turning track 124. Because it 124 is a single piece, and attached to each side of the forearm/hand bars 110, this turning track 124 also serves the function of a yoke, holding together the two forearm/hand bars 110. Because they 110 are now fastened together, the two forearm/hand bars 110 can: a) only move together in unison, left or right, to steer the cycle 1, orb) move rotationally together “up and down”, to provide torque to the crank axle 35. Located inside the turning track 124 is a horizontally stationary carriage 125 (As shown in FIGS. 7, 8, 8 a, 8 b 9, 14, and 15). The carriage 125 consists of an attachment bracket 123 b and several rollers 125 a affixed to the carriage 125. The rollers 125 a of this carriage 125 fit inside the turning track 124, and permit the turning track 124 to roll over the horizontally stationary carriage 125 as the rider steers the forearm/hand bars 110 to the right or left, as shown in FIGS. 7, 8, 8 a, 8 b, 9, and 15. However, for someone skilled in the art, turning track designs other than that used in this enablement are anticipated. For example, a curved linear rail may be employed or some other type of rail or curved bar system.

The attachment bracket 123 b on the carriage 125 is operatively connected to a horizontally positioned rod 125 b on its 125 b front end, and to the top of a diagonally positioned telescoping rod 126 on its rear end. In between the carriage 125 and the telescoping rod 126, this same horizontal rod 125 b is attached to a vertically mounted connecting bridge rod 226, which has two rod end bearings 226 a and 226 b on either end of it 226. The purpose of the carriage 125 and its rollers 125 a are to permit the rider to steer the front wheel 18 of the cycle 1 to either his right or left, while at the same time pumping the forearm/hand bars 110 “up and down”, which continuously provides torque to the crank axle 35 and the rear wheel 17. (See FIGS. 8, 8 a, 8 b, 9, 14, and 15) The carriage 125 accomplishes this function by having multiple rollers 125 a mounted on it 125. Some of the rollers 125 a are mounted onto the carriage 125 so that they only touch the interior surface of the turning track's 124 front curve, while the other rollers 125 a simultaneously only touch the interior surface of the turning tracks rear curve. (See FIGS. 8, 8 a, 8 b, 9, 14, and 15) These rollers 125 a are always in contact with and ride the interior surfaces of the turning track 124. Thus, whenever the rider steers the cycle 1, by turning his forearm/hand bars 110 to his right or left, these rollers 125 a, rotate and permit the turning track 124 to rotate over them. Because the carriage 125 is attached to the top of the horizontally stationary telescoping rod 125 c, the carriage 125 always stays in a horizontally stationary position relative to its position with the top tube 2 of the bike 1. This occurs as a result of the base of the telescoping rod 126 a being affixed at its base to the bicycle frame-such as the head tube 6. (See FIGS. 8, 8 a, 8 b, 9, 10, 14, and 15) Because of this unique design, even though the rider is using his forearm/hand bars 110 to turn and steer the front wheel 18 of the bicycle 1 to his left or right, he can simultaneously and rotationally pump his forearm/hand bars 110 “up and down”, and thereby continuously input torque into the crank axle 35 from energy expended using muscles located only in his upper body. (See FIGS. 7a -1 thru 7 a-4, 8, 8 a, 8 b, 9, 14, and 15)

The horizontal rod 125 b, attached on its front end to the carriage 125 and to the top of the telescoping rod 126 on its rear end, has affixed in between these two end points an upper rod end bearing 226 a. Attached to the bottom end of this rod end bearing 226 a is the top end of the vertically positioned connecting bridge rod 226. The bottom end of this connecting bridge rod 226 has attached to it a lower rod end bearing 226 b. The bottom end of the lower rod end bearing 226 b is affixed to the outer end of the crank 227. The inner end of the crank 227 is attached to a solid drive line 229 that will rotate. (See FIGS. 7a -1 thru 7 a-4, 9, 14, and 15) Thus, as the rider rotationally pulls-up and pushes-down on the forearm/hand bars 110, this causes the connecting bridge rod 226, to also move in unison up and down. Because the inner end of the crank 227 is affixed to a stationary positioned solid drive line 229, the up and down movement of the connecting bridge rod 226 causes the crank 227 to rotate in unison with both the bridge rod 226 and the oscillating forearm/hand bars 110. The drive line 229, attached on its front end to the inner end of the crank 227, then also rotates in concert with the rotation of the crank 227. (See FIGS. 7a -1 thru 7 a-4, 9, 14, and 15) A solid rod or tube, used for the horizontal drive line 229, is connected on its rear end with a bevel gear 334 a or 445 a, which is positioned near or inside the top of the down tube 3. The reason that the solid horizontal drive line 229 is able to be connected to the upper front crank 227 on its 229 front end and bevel gear 334 a or 445 a on its rear end, is because it 229 is positioned in such a way that it 229 traverses a gap between the crown in the forks 19 and the top of the front wheel 18 and tire 6. (See FIGS. 7, 9, 10, 14, 15, and 16) Normally, the use of a solid drive line 229 in this configuration would preclude the rider from being able to turn the bicycle 1 to the right or left because the solid drive line 229 is not flexible, and will not bend with the left or right directional steering of the front wheel 18.

The solution to this problem is to make the front wheel 18 steering function independent from the rider's vertical pumping of his forearm/hand bars 110 as he provides torque to the driving wheel 17. One means for separating and making independent the turning function from the forearm/hand power function is by use of the turning track 124, carriage 125 affixed to rollers 125 a, telescoping rod 126, and connecting bridge rod 226 attached to the stationary positioned crank 227 affixed to the front end of the solid drive line 229, as shown in FIGS. 7a -1 thru 7 a-4, 8, 8 a, 8 b, 9, 14, and 15.

Another important set of component parts are the cam 230, cam follower 231, spring set and its housing 232. As the rider pushes and pulls his pumping forearm/hand bars 110, he is rotating both the crank 227 and horizontal rotating rod 229. The current invention utilizes cam 230, cam follower 231, and cam follower spring set 232 to push the upper front crank 227 over its 227 top and bottom dead center positions. (See FIGS. 9, 10, 14, and 15) During each revolution of crank axle 35 and upper front crank 227, the upper front crank 227 may stop rotating due to it 227 having been rotated into its 227 top or bottom dead center positions at 0 and 180 degrees, respectively. (See FIGS. 7a 1-7 a-4, 10, 14 and 15) When this occurs, the forearm/hand bars 110 cannot be moved either up or down. In order to ensure a complete 360 degree rotation of the crank 227, and a corollary complete up and down oscillation of the forearm/hand bars 110 by the rider, the crank 227 must be pushed over its 227 top and bottom dead center positions. The reason for this is because the crank's 227 rotational momentum is not always sufficient to push it 227 over the crank's 227 top and bottom dead center positions. Thus, this function is accomplished through use of the cam 230, cam follower 231, and spring mechanism 232 attached to the cam follower 231, as illustrated in FIGS. 7a 1-7 a 4, 9, 10, 14 and 15).

The cam 230 may have the general shape of an ellipse. The cam follower 231 and spring-loaded cam follower tower 232 are designed such that the spring 232 will be in its 232 most upward and loaded position when cam follower 231 is just cresting the shoulder on the circumference of cam 230 and ready to drop over its 230 circumferential shoulder. As the cam follower 231 drops over the shoulder on the circumferential surface of cam 230, the energy loaded spring mechanism 232 releases its 232 stored energy and forces the cam follower 231, to which it 232 is attached, to travel and rotate over the circumferential surface of the cam 230, causing it 231 to continue its 231 full run over the geometric circumferential surface of the cam 230 to the next cam shoulder 230, located 180 degrees away from the first cam shoulder 230. (See FIGS. 9, 10, 14, 15, and 16) During this forced rotation of the cam 230, it 230 causes the horizontal solid drive line 229 to rotate, which in turn causes the upper front crank 227 to be mechanically pushed over its 227 top and bottom dead center positions at 0 and 180 degrees. Thus, upper front crank 227 is able to complete its 360 degree rotation as shown in FIGS. 7a -1 thru 7 a-4.

B. Middle Drive System 300 Applicable Only to Configuration II

The rear end of solid drive line 229 engages with the front axle of a set of bevel gears 334 a and 334 b positioned near the top end of down tube 3. As this drive line 229 rotates, it 229 causes the set of bevel gears 334 a and 334 b to rotate in unison with it 229, as shown in FIGS. 6 and 11. Bevel gear 334 b has attached on the end of it an axle 335, which axle 335 is connected to a spur gear 336, as shown in FIG. 11. Spur gear 336 has gear teeth positioned around its 336 circumference; a second spur gear 337, as shown in FIG. 11, also has gear teeth located around its 337 circumference. The circumferential gear teeth on spur gear 336 are meshed into the circumferentially positioned gear teeth on spur gear 337. (See FIG. 11) Thus, when bevel gear 334 a is rotated from the rotation of rotating rod 229, it 334 a rotates bevel gear 334 b, which in turn rotates spur gear 336. The rotation of spur gear 336 then rotates spur gear 337. Attached to the back side of this upper spur gear 337, are upper front chain mid-level sprockets 338 and 338 a, which rotate in unison with spur gear 337, to which it 338 is attached. (See FIG. 11).

Utilizing the design of Configuration II, the Dual Power bicycle 1 gives the rider the ability to vary the number of oscillations per minute that he uses in pumping his forearm/hand bars 110. It 1 accomplishes this through the use of multiple sprockets 338 and 338 a. Chain 340 fits over any of sprockets 338 or 338 b. The mechanism used to transfer chain 340 from one sprocket 338 to the next 338 a is called an upper front derailleur 339. (See FIG. 9) A cable is attached to upper front derailleur 339. A shift lever 339 a is attached to a controller cable. Thus, when the rider moves shift lever 339 a, it causes a like movement of the cable to which it is attached. Because this cable is attached to the upper front left derailleur 339, the movement of cable lever 339 a causes a movement in the upper front derailleur 339, which then moves the chain 340 onto the desired sprocket 338 or 338 a. (See FIG. 9) This ability, modulating the rate of forearm/hand bar 110 oscillations, permits the rider to optimize the amount of torque that he is delivering into rotation of the driving wheel 17. At the same time, it affords the rider the most comfortable and efficient use of his legs/feet and forearm/hands 110 to simultaneously power the bicycle 1.

A chain or belt 340 fits over a set of the teeth around the circumference of sprockets 338 or 338 a. The rear end of this chain or belt 340 fits directly over the outer circumferentially located teeth on lower sprocket 341. This sprocket 341 is affixed to crank axle 35, as shown in FIG. 12. Because sprocket 341 is attached directly to crank axle 35, the rotation of sprocket 341 causes the simultaneous rotation of crank axle 35. (See FIG. 12) Because crank axle 35 is operatively connected to driving wheel 17, through a standard set of bicycle chain, sprockets, cassettes, and gears, Dual Power torque provided from the rider's upper body and arms causes crank axle 35 to rotate, which concurrently inputs torque into driving wheel 17, which causes it 17 to rotate and move the rider and bicycle 1 forward. (See FIGS. 1 and 12).

V. Dual Power Cycle Drive Train for Configuration III of the Invention

A. Upper Drive System 100 for Configurations I, II, and III:

All of the preceding Enablement describing Upper Drive System 100 for Configurations I, II and III is adopted and incorporated herein as though set forth fully.

B. Enablement for Middle Drive System 400 Applicable Only to Configuration III of the Dual Power Drive Train

The primary differences between Configuration II and Configuration III are found in the use of different components for Middle Drive Systems 300 and 400. For example, the horizontal driveline 229 is positioned in both Middle Drive Systems 300 and 400 so that it traverses through the front wheel 18 and crown of the forks 19, and then immediately attaches to bevel gear 334 a in Configuration II, (See FIG. 11). However, in Configuration III, after traversing this same gap between the crown of the forks 19 and the top of the front wheel 18, this same driveline 229 immediately enters into an opening in a cover 443 located at the top of the down tube 3. (See FIG. 13) After traversing through this opening in cover 443, the rear end of it 229 is then connected to bevel gear 445 a, and causes it 445 a to rotate in unison with the horizontal drive line 229. The teeth from bevel gear 445 a are meshed with the teeth of its companion bevel gear 445 b. A second rotating drive line 446 is positioned diagonal to drive line 229, and it 446 is attached on its front end to bevel gear 445 b. (See FIG. 16) This second rotating drive line 446 traverses inside and parallel with down tube 3, and the rear end of diagonal drive line 446 is attached on its rear end with another set of bevel gears 448 a and 448 b, which are affixed to crank axle 35. (See FIGS. 16 and 17)

The lower rear end of rotating diagonal drive line 446 is attached to the front end of the axle for bevel gear 448 a, whose gears are meshed into those of bevel gear 448 b. This bevel gear 448 b is positioned and attached to crank axle 35. Thus, as the upper set of bevel gears 445 a and 445 b, along with diagonal drive line 446, are rotated from turning of the upper front rotating drive line 229, they, 445 a, 445 b, and 446 cause the lower set of bevel gears 448 a and 448 b to rotate. Because bevel gear 448 b is attached to the crank axle 35, the rotation of bevel gears 448 a and 448 b cause crank axle 35 to also rotate in unison with them 448 a and 448 b. (See FIGS. 16 and 17) As a result of energy emanating from the rider's up and down arc-shaped oscillations of his forearm/hand forearm bars 110, and the corresponding rotation of the component parts of the Dual Power drive train described in this Enablement, crank axle 35 is rotated providing torque and power to the drive wheel 17. This permits the rider to have the benefits of Dual Power bicycling. It should be understood that if the rotating diagonal drive line 446 does not have gears coupled thereto to adjust the rate of rotation, then the cam 230 and cam follower 231 may be coupled to the lower crank axle 35.

In the case wherein the Dual Power bicycle 1 provides the rider with the ability to vary the number of oscillations per minute that he uses in pumping his forearm/hand bars 110, a multi speed internal gear hub 449 can be positioned inside down tube 3. An example of such an internal multi-speed gear mechanism is a Sturmey-Archer multi-speed internal gear hub. This internal gear hub 449 may be connected on one of its 449 ends to the rear end of rotating drive line 229, and on its 449 opposite end to bevel gear 445 a. The positioning of the internal gears for internal gear hub 449 can be controlled by a small cable that protrudes out of its 449 rear end, adjacent to the diagonally installed bevel gear 445 b inside the down tube 3. This cable travels from inside the internal multi-gear hub 449, through the center of bevel gear 445 a, to a lever 449 a located outside of the down tube 3, and controlled by the rider through movement of the lever 449 a, which moves the chain connecting it 449 a with the internal hub gears 449. (See FIG. 16).

On demand Dual Power riding is made possible through the installation of a one-way bearing 450. In Configuration III, the one-way bearing 450 is attached to the crank axle 35 on its inner race. The outer race is attached to the interior surface of the back of bevel gear 448 b. (See FIG. 17) If the rider is pedaling the crank axle 35 with his legs at a faster RPM than he is pumping the forearm/hand bars 110 to turn the crank axle 35, then the energy from pumping his forearm/hand bars 110 will not input any torque into the rotation of the crank axle 35. On the other hand, if the rider is pumping his forearm/hand bars 110 and rotating the crank axle 35 at a faster RPM than he is pedaling the pedals 11 a and 12 to turn the crank axle 35, then all of the energy to rotate the crank axle 35 will be inputted from the rider's muscles in his upper body and arms as he rotationally pumps forearm/hand bar 110. In the case where the rider is causing the crank axle 35 to rotate at the same RPM, from both oscillating forearm/hand bars 110 and use of his legs to rotate the pedals, then both the rider's upper body and lower body muscles will be simultaneously inputting torque to cause the rotation of the crank axle 35. And in the case where the rider is pedaling the crank axle with just his legs at a faster rate than he is rotationally oscillating his forearm/hand bars 110, all of the torque used in moving the bike 1 will be from his legs. (See FIGS. 16 and 17)

Some government and industry regulations require that the bicycle front wheel 18 be able to steer to its 18 right and left direction at a minimum of 45 degrees from its 18 center or straight forward position. Most currently designed front forks 19 will not permit the front wheel 18 to steer 45 degrees in combination with using a Dual Power drive train as enabled herein. The reason for this is that currently designed front forks 19 generally measure 3″ to 4″ at the crown, and 4″ to 5″ at the bottom, where they 19 attach to the front wheel 18 axle. The currently used 3″ to 4″ width at the crown in the forks 19 is too narrow for use with a Dual Power drive train and still be able to make a 45 degree turn. The reason for this is the top interior side of the front forks 19 will touch and conflict with the solid horizontal drive line 229 before the front wheel 18 has turned 45 degrees to its 18 right or left from its 18 center position. Thus, when a bicycle 1 or other vehicle uses a Configuration II or III Dual Power drive train, its front forks 19 will need to be wide enough at their crown to permit the forks 19 to steer the front wheel 18 at least 45 degrees to its 18 right or left before one of the forks 19 touches, or conflicts with, the horizontal solid drive line 229. The wider that the diameter of the solid drive line 229 is will require a larger opening in the crown of the front forks 19 than will a more narrow solid drive line 229. The bottom of the forks 19 can continue to accommodate currently used front wheel 18 axle widths.

In conjunction with the need for the front forks 19 to be wide enough at their crown to avoid conflicting with the solid drive line 229 in a 45 degree turn, the circumference of the turning track arc 124 needs to be sufficiently sized to accommodate both the 45 degree steering requirement as well as the additional length to accommodate the width of the carriage 125 and its rollers 125 a during a left or right turn.

Although the above-preferred embodiments have been illustrated and described, persons skilled in the art will recognize that many changes to the specific embodiments disclosed above could be made without departing from the spirit of the invention. Therefor the invention is not limited thereto except insofar as such limitations are included in the following claims and allowable functional equivalents thereof. 

1. A dual powered propulsion system for use with a human powered vehicle, the system comprising: a connecting rod, wherein a front end of the connecting rod is operatively coupled to forearm bars and a rear end of the connecting rod coupled to a splitter, wherein the splitter is coupled to a first rack and a second rack; a first pinion gear coupled to a crank axle with a first one-way bearing; and a second pinion gear coupled to the crank axle with a second one-way bearing, wherein the first pinion gear rotates in a direction opposite the second pinion gear, wherein: the first rack is coupled below and engages the first pinion gear and the second rack is coupled above and engages the second pinon gear; the first and second racks oscillate back and forth from movement by the connecting rod in response to movement of the forearm bars in an up power stroke and a down power stroke; and the first pinion gear and the second pinion gear supply rotational power to the crank axle in a single direction in response to the oscillation of the first and second racks and the operation of the respective one-way bearings.
 2. The system of claim 1, further comprising rollers coupled to the vehicle, wherein the rollers engage the first rack to maintain engagement with the first pinion gear and the rollers engage the second rack to maintain engagement with the second pinion gear, or rack support casings supporting the first rack and the second rack to maintain engagement with the first pinion gear and the second pinion gear respectively as the first rack travels over the first pinion gear and the second rack travels over the second pinion gear.
 3. The system of claim 2, wherein the rollers or the rack support casings are coupled to the vehicle with a housing to maintain the rollers or rack support casings in fixed positions.
 4. The system of claim 1, further comprising a turning track operatively coupled to the forearm bars and a carriage, wherein the carriage is operatively coupled to the connecting rod.
 5. The system of claim 4, wherein the carriage further comprises roller devices coupled to the carriage over which the turning track travels to the right or left.
 6. The system of claim 5, further comprising a telescoping rod coupled to a frame of the vehicle on one end and operatively coupled to the carriage on the other end, wherein the telescoping rod allows the carriage to move up and down in response to movement of the forearm bars in up and down power strokes while prohibiting side to side movement of the carriage.
 7. The system of claim 6, wherein the turning track travels over the roller devices on the carriage and allows the forearm bars to turn a front wheel or wheels of the vehicle left and right and simultaneously move the carriage up and down in response to movement of the forearm bars in up and down power strokes.
 8. The system of claim 7, wherein the connecting rod oscillates back and forth, and up and down, in response to movement of the carriage up and down within a vertical plane.
 9. The system of claim 6, further comprising elbow platforms coupled to the forearm bars, each elbow platform comprising a manual locking mechanism for coupling an elbow to the elbow platform.
 10. The system of claim 9, further comprising quick release bindings coupled to each elbow platform, wherein the quick release bindings are configured to releasably couple the elbow platform to the forearm bars.
 11. The system of claim 9, wherein the forearm bars and elbow platforms operatively provide four point steering of the bicycle.
 12. A dual powered propulsion system for use with a human powered vehicle, the system comprising: a turning track operatively coupled to forearm bars; a carriage operatively coupled to the turning track, wherein the carriage is operatively coupled to a connecting rod and to a crank axle; and a telescoping rod coupled to a frame of the vehicle on one end and operatively coupled to the carriage on the other end, wherein: the telescoping rod allows the carriage to move up and down in response to movement of the forearm bars in up and down power strokes while prohibiting side to side movement of the carriage as the turning track moves right or left with respect to the carriage; and the crank axle operatively receives forward propelling power in response to movement of the forearm bars in up and down power strokes.
 13. The system of claim 12, wherein the carriage further comprises roller devices coupled to the carriage over which the turning track travels to the right or left.
 14. The system of claim 12, wherein the turning track travels over the roller devices and allows the forearm bars to turn a front wheel of the vehicle left and right and simultaneously move the carriage up and down in response to the movement of the forearm bars in up and down power strokes.
 15. A dual powered propulsion system for a vehicle, the system comprising: forearm/hand bars moveably coupled to a fulcrum bar of the vehicle, wherein the forearm/hand bars are moveable in unison with up and down power strokes to power a drive system for providing propulsion to the vehicle; and a steering system, the steering system operatively coupled to the forearm/hand bars, wherein the forearm/hand bars steer the vehicle in response to turning of the forearm/hand bars left or right to operatively turn the steering system, and wherein simultaneously providing propulsion to the vehicle functions independently from steering the vehicle.
 16. The vehicle of claim 15, further comprising at least one platform coupled to the forearm/hand bars, wherein the at least one platform supports elbows of a rider during movement of the forearm/hand bars in the up and down power strokes in a rotational arc shape.
 17. The vehicle of claim 15, further comprising a crank operatively coupled to the forearm/hand bars, wherein movement of the forearm/hand bars in up and down power strokes delivers torque to the crank.
 18. The vehicle of claim 17, further comprising a connecting rod coupled to a yoke of the forearm/hand bars on an upper end and coupled to an end of the crank on a lower end, a solid horizontal drive rod, coupled on one end to the crank, on an opposing end to a middle drive system; wherein movement of the forearm/hand bars in up and down power strokes moves the upper end of the connecting rod in a vertical up and down direction and moves the lower end in a circular direction as it rotates the crank 360 degrees and delivers torque to the middle drive system.
 19. The vehicle of claim 18, further comprising a cam and a cam follower mechanism located between the upper front crank and the middle drive system or located at a lower crank axle, wherein the cam is operatively coupled to the solid horizontal drive rod and the cam follower mechanism engages the cam to push the solid horizontal drive rod through its top and bottom dead center positions during a complete rotation of the solid horizontal drive rod.
 20. The vehicle of claim 15, further comprising a turning track coupled to the forearm/hand bars, wherein the turning track comprises a predetermined arc length and a carriage engaged within the turning track.
 21. The vehicle of claim 20, wherein the carriage is maintained in a stationary horizontal position by a telescopic rod coupled between a stationary portion of the vehicle and the carriage, wherein the telescopic rod allows for the carriage to move up and down in response to the up and down power strokes of the forearm/hand bars.
 22. The vehicle of claim 21, wherein lateral rotation of the forearm/hand bars moves the turning track with respect to the carriage, wherein the arc length of the turning track provides the steering range rotation of the forearm/hand bars.
 23. A dual powered propulsion system for a bicycle, the system comprising: forearm/hand bars moveably coupled to a fulcrum bar of the bicycle, wherein the forearm/hand bars are moveable in unison with up and down power strokes to power a drive system for providing propulsion to the bicycle; a set of forks operatively coupled to the forearm/hand bars, wherein the forearm/hand bars steer the vehicle right or left in response to turning of forearm/hand bars, which simultaneously turn the set of forks right or left, and wherein providing propulsion to the bicycle functions independently from steering the bicycle; a turning track coupled to the forearm/hand bars, wherein the turning track comprises a predetermined arc length and a stationary carriage engaged within the turning track; and comprising a solid horizontal rotating drive rod extending through a gap between a crown in the fork of the bicycle and a top of a front wheel, the solid horizontal rotating drive rod operatively coupled to the forearm/hand bars, wherein movement of the forearm/hand bars in up and down power strokes rotates the solid horizontal drive rod.
 24. The bicycle of claim 23, further comprising a crank operatively coupled to the forearm/hand bars, wherein movement of the forearm/hand bars in the up and down power strokes delivers torque to the crank.
 25. The bicycle of claim 22, further comprising a connecting rod coupled to a yoke of the forearm/hand bars on an upper end and coupled to an end of the crank on a lower end, wherein movement of the forearm/hand bars in the up and down power strokes moves the upper end of the connecting rod in a vertical up and down direction and moves the lower end in a circular direction as it rotates the crank 360 degrees.
 26. The bicycle of claim 22, further wherein the solid horizontal rotating drive rod is coupled on one end to the crank and on an opposing end to a middle drive system, wherein rotation of the crank 360 degrees rotates the solid horizontal drive rod 360 degrees.
 27. The bicycle of claim 23, wherein torque is supplied to the middle drive system in response to rotation of the solid horizontal drive rod.
 28. The bicycle of claim 27, further comprising a cam and a cam follower mechanism located between the crank and the middle drive system or located at a lower crank axle, wherein the cam is coupled to the solid horizontal rotating drive rod and the cam follower mechanism engages the cam to push the crank through its top and bottom dead center positions during a complete rotation of the crank.
 29. The bicycle of claim 24, wherein the middle drive system comprises a chain derailleur operatively coupled to multiple sprockets of a drive train, each sprocket having a different diameter, and a chain coupled between one sprocket of the multiple sprockets to transfer torque from the upper rotating horizontal rod to the lower crank axle.
 30. The bicycle of claim 29, wherein the derailleur and multiple sprockets permit a rider to modulate the number of oscillations per minute with the forearm/hand bars compared to the RPM's of his legs rotating the lower crank axle.
 31. The bicycle of claim 24, wherein the middle drive system comprises an internal gear hub attached to a rotating rod of a drive train, the rotating rod positioned diagonally in a downtube of the vehicle having bevel gears on a front end to couple to the internal gear hub and bevel gears on a rear end coupled to a lower crank axle, which will permit a rider to modulate a number of vertical oscillations per minute with his forearm/hand bars compared to the revolutions per minute of his legs rotating the lower crank axle.
 32. The bicycle of claim 31, wherein the rotating rod of the drive train of the middle drive system engages and rotates the lower crank axle.
 33. The bicycle of claim 23, wherein the carriage is maintained in a stationary horizontal position by a telescopic rod operatively coupled between a stationary portion of the vehicle and the horizontal stationary carriage, wherein the telescopic rod allows for the carriage to move up and down in response to the up and down power strokes of the forearm/hand bars without moving laterally left or right.
 34. The bicycle of claim 33, wherein lateral turning of the forearm/hand bars laterally moves the turning track with respect to the carriage, wherein the arc length of the turning track provides the horizontal steering range of rotation of the forearm/hand bar. 